BACKPRESSURE REGULATOR FOR EASY PUMP START-UP
A system and method for automatically performing start-up and overpressure relief functions in association with a primary fluid carrier such as, for example, a liquid handling pipeline or tank. The system includes a main valve for primarily exhausting air from the system as it fills with a liquid. A start-up pilot device is also provided for exhausting air from the system upon start-up, but prior to the main valve opening. Finally, an overpressure pilot device is provided to relieve overpressure situations during normal operation.
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The priority benefit of U.S. Provisional Patent Application No. 61/746,636, filed Dec. 28, 2012, is hereby claimed and the entire contents thereof are incorporated herein by reference.
FIELD OF THE DISCLOSUREThe present disclosure relates to fluid delivery and handling systems and, more particularly, to systems and methods for providing start-up and overpressure relief functionality for liquid delivery and handling systems.
BACKGROUNDLiquid delivery and handling systems such as, for example, industrial fire sprinkler systems are adapted to accommodate a liquid such as water under pressure. As such, when the system is activated the pressurized water is exhausted through any number of nozzles or sprinklers for extinguishing the fire. Upon initial installation, for example, the various pipelines, valves, nozzles, and sprinklers art not filled with water, but rather, contain air at generally atmospheric pressure. When the system is filled with water, a process that can be referred to as “start-up,” the air in the system must be exhausted through some sort of exhaust valving arrangement. This exhausting of the air can be referred to as “start-up relief.” Many conventional exhaust valving arrangements include manually operable valves, which are opened upon “start-up” and manually closed when all the air is exhausted. Once all the air is exhausted, the system is completely filled with water and pressurized to a target pressure. Increases in pressure above the target pressure, which can result from environmental changes or changes in the source of water supply, for example, and can detrimentally affect the operation and useful life of the system. Therefore, some conventional systems also include an overpressure relief valving arrangement that is configured to relieve the pressure in the system back down to the target pressure, a process which can be referred to as “overpressure relief.” Some conventional overpressure relief valving arrangements are either manually operated in response to an alarm, for example, or operate based on the sensing of pressure in the system. Regardless of the specific exhaust and relief valving arrangements conventionally used, the two arrangements operate independently of each other and require at least some amount of user input or attention to ensure proper “start-up relief” and/or “overpressure relief” functionality.
SUMMARYOne aspect of the present disclosure provides a fluid control system for providing start-up and overpressure relief functions to a primary fluid carrier. The system can include a main valve, a start-up pilot device, and an overpressure pilot device. The main valve can have an inlet, an outlet, a gallery disposed between the inlet and the outlet, a valve seat fixedly disposed in the gallery, and a valve plug slidably disposed in the gallery between a closed position engaging the valve seat and an open position spaced away from the valve seat. The valve plug can be biased toward the closed position via a control spring. The start-up pilot device and the overpressure pilot device can each include a valve body and a control assembly including a diaphragm having opposite first and second surfaces and operably coupled to a valve plug. The valve body can include an inlet port, an outlet port, and a valve port disposed between the inlet port and the outlet port, wherein the valve plug can be movable between a closed position engaging the valve port and an open position spaced away from the valve port. In some versions, the valve plug of the start-up pilot device can be biased toward the open position by a start-up control force applied to the first surface of the diaphragm of the start-up pilot device, and the valve plug of the overpressure pilot device is biased toward the closed position by an overpressure control force applied to the first surface of the diaphragm of the overpressure pilot device.
The system can further include a first supply line providing fluid communication between the inlet of the main valve, the inlet port of the start-up pilot device, and the gallery of the main valve. The system can further include a first exhaust line providing fluid communication between the outlet port of the start-up pilot device and the outlet of the main valve. The system can further include a first sensing line providing fluid communication between the second surface of the diaphragm of the start-up pilot device and a first registration source. The system can further include a second sensing line providing fluid communication between the second surface of the diaphragm of the overpressure pilot device and a second registration source. The system can further include a second exhaust line providing fluid communication between the outlet port of the overpressure pilot device and the outlet of the main valve. Finally, the system can further include a second supply line providing fluid communication between the inlet port of the overpressure pilot device and the gallery of the main valve.
The present disclosure is related to systems and methods for automatically performing start-up relief and overpressure relief functions in association with a primary fluid carrier such as, for example, a liquid handling pipeline or tank.
To facilitate the desired operation in each of these situations, the system 10 of
With continued reference to
The start-up pilot device 16 of the example in
The first surface 56 of the diaphragm 52 is engaged by the loading spring 54 such that the loading spring 54 applies a start-up control force to bias the diaphragm 52 and the valve plug 50 toward the open position. In the disclosed version of the start-up actuator device 16, this means that the loading spring 54 biases the diaphragm 52 and the valve plug 50 downward relative to the orientation of
As shown in
Still referring to
The first surface 82 of the diaphragm 78 is engaged by the loading spring 80 such that the loading spring 80 applies an overpressure control force to bias the diaphragm 78 and the valve plug 76 toward the valve port 70 and into the closed position. In the disclosed version of the overpressure pilot device 18, this means that the loading spring 80 biases the diaphragm 78 and the valve plug 76 toward the right relative to the orientation of
As shown in
As mentioned, the start-up and overpressure pilot devices 16, 18 of the system 10 depicted in
Specifically, with reference to the start-up pilot device 16 in
In the version depicted in
Referring now to the overpressure pilot device 18 depicted in
With the system 10 of
More specifically, upon start-up, the pipeline 12 and therefore the system 10 can be completely filled with air, or partly filled with air and the remainder filled with operating fluid such as water or generally some other fluid. After initiating start-up, a pump located upstream from the system 10 begins pumping water into the pipeline 12.
As water begins to fill the pipeline 12, the pressure of the air remaining in the system 10 may be relatively low, but also beginning to increase as it is compressed under the force of the emerging water. At these low pressures, the air at the inlet 22 of the main valve 14 is insufficient to open the valve plug 30 of the main valve 14, and as such, it is exhausted to the outlet 24 of the main valve 14 via the start-up supply line 88, the normally open start-up pilot device 16, and the start-up exhaust line 92. This ensures a fast and efficient start-up process.
As the pressure of the fluid at the inlet 22 of the main valve 14, it ultimately forces the valve plug 30 of the main valve 14 away from the valve seat 28 and into an open position to exhaust any remaining air in the system 10 directly through the gallery 26 and to the outlet 24 of the main valve 14. The increase in pressure at the inlet 22 of the main valve 14 is also ultimately sensed by the second surface 60 of the diaphragm 52 of the start-up pilot device 16 via the start-up supply line 88, inlet port 40, and sensing line 60, which will ultimately and automatically force the start-up pilot device 16 into the closed position.
With the start-up pilot device 16 closed, fluid pressure in the start-up supply line 88 is communicated to the top of the gallery 26 of the main valve 14, above the valve plug 30, via the second line portion 88b of the start-up supply line 88. As this pressure in the gallery 26 ultimately becomes equal to the pressure at the inlet 22 of the main valve 14, the loading of the control spring 32 in the gallery 26 closes the valve plug 30. This terminates the start-up function and the system 10 is completely closed, at which point, fluid in the pipeline 12 is maintained at the desired target pressure.
If an environmental or other change causes the pressure in the pipeline 12, and therefore in the inlet 22 of the main valve 14, to increase above the desired target pressure and above a pre-set threshold pressure, the overpressure pilot device 18 automatically responds to relieve that excess pressure and return the pipeline 12 and system 10 to the target pressure.
Specifically, during the normal operating condition, the overpressure pilot device 18 occupies its normally closed position due to the force generated by the loading spring 80 on the first surface 82 of the diaphragm 78. In this closed position, the valve plug 76 is seated against the valve port 70, thereby preventing fluid from flowing from the inlet port 66 to the outlet port 68.
However, the pressure at the inlet 22 of the main valve 14 is continuously monitored by the second surface 84 of the overpressure pilot device 18 via the sensing line 86. Thus, in the event the pressure at the inlet 22 of the main valve 14 exceeds a predetermined threshold pressure, which is set by the overpressure control force generated by the loading spring 80 of the overpressure pilot device 18, the diaphragm 78 will sense the pressure in the sensing line 86 and automatically move the valve plug 76 to the left relative to the orientation of
Thus, from the foregoing, it should be appreciated that the system 10 disclosed in
The system 10 in
While the pilot devices 16, 18 of the system 10 have thus far been described and depicted as including loading springs 54, 80 providing the start-up and overpressure control forces to open the start-up pilot device 16 and close the overpressure pilot device 18, respectively, in an alternative version not shown, the system 10 could also include an adjustable external source of pressurized air in communication with the first surface 56 of the diaphragm 52 of the start-up pilot device 16 and/or the first surface 82 of the diaphragm 78 of the overpressure pilot device 18. The external source of pressurized air could be used in addition to the loading springs 54, 80 or as a substitute for the loading springs 54, 80 for creating the start-up and/or overpressure control forces, depending on the circumstances of the application.
Thus, it should be appreciated that the system and method described with reference to
For example,
While the system 10 of the present disclosure has thus far been described as including a start-up pilot device 16 and an overpressure pilot device 18 that is a separate physical structure from the start-up pilot device 16, the system 10 could also be constructed in a manner in which the start-up and overpressure pilot devices 16, 18 are combined into a single device, e.g., a single physical construct. For example, in such a system 10, the various components of the start-up and overpressure pilot device 16, 18 could be machined into, cast into, or otherwise formed from a single block of material (e.g., a metal material) or multiple blocks of material secured together. So configured, the two pilot device 16, 18 could function as two separate devices, although they reside within a common physical device, as opposed to the two separate devices depicted in
Thus a variety of changes and modifications to the system 10 can be useful depending on a desired end application and such changes and modifications are intended to be within the scope of the disclosure. Accordingly, the scope of the invention is not to be defined by the examples discussed herein and shown in the attached figures, but rather, the claims that are ultimately issued in a patent and all equivalents thereof.
Claims
1. A fluid control system for providing start-up and overpressure relief functions to a primary fluid carrier, the system comprising:
- a main valve having an inlet, an outlet, a gallery disposed between the inlet and the outlet, a valve seat fixedly disposed in the gallery, and a valve plug slidably disposed in the gallery between a closed position engaging the valve seat and an open position spaced away from the valve seat, the valve plug being biased toward the closed position via a control spring;
- a start-up pilot device and an overpressure pilot device, each of the start-up and overpressure pilot devices including a valve body and a control assembly including a diaphragm having opposite first and second surfaces and operably coupled to a valve plug, the valve body including an inlet port, an outlet port, and a valve port disposed between the inlet port and the outlet port, the valve plug movable between a closed position engaging the valve port and an open position spaced away from the valve port,
- wherein the valve plug of the start-up pilot device is biased toward the open position by a start-up control force applied to the first surface of the diaphragm of the start-up pilot device, and the valve plug of the overpressure pilot device is biased toward the closed position by a overpressure control force applied to the first surface of the diaphragm of the overpressure pilot device;
- a first supply line providing fluid communication between the inlet of the main valve, the inlet port of the start-up pilot device, and the gallery of the main valve;
- a first exhaust line providing fluid communication between the outlet port of the start-up pilot device and the outlet of the main valve;
- a first sensing line providing fluid communication between the second surface of the diaphragm of the start-up pilot device and a first registration source;
- a second sensing line providing fluid communication between the second surface of the diaphragm of the overpressure pilot device and a second registration source;
- a second exhaust line providing fluid communication between the outlet port of the overpressure pilot device and the outlet of the main valve; and
- a second supply line providing fluid communication between the inlet port of the overpressure pilot device and the gallery of the main valve.
2. The system of claim 1, wherein at least one of the first and second registration sources is the inlet of the main valve.
3. The system of claim 1, wherein the first registration source is the inlet of the main valve and the first sensing line includes a pitot tube providing fluid communication between the inlet port of the start-up pilot device and the second surface of the diaphragm of the start-up pilot device.
4. The system of claim 1, wherein at least one of the first and second registration sources is external to the main valve.
5. The system of claim 1, wherein the control spring of the main valve directly engages the valve plug of the main valve to bias the valve plug toward the closed position.
6. The system of claim 1, wherein the start-up pilot device includes a start-up control spring providing the start-up control force, and the overpressure pilot device includes an overpressure control spring providing the overpressure control force.
7. The system of claim 1, further comprising a restrictor coupled into the first supply line between the inlet of the main valve and the inlet port of the start-up pilot device.
8. The system of claim 6, wherein the restrictor includes one of an adjustable restrictor or an orifice plate.
9. The system of claim 1, wherein the start-up pilot device and the overpressure pilot device are separate physical structures.
10. The system of claim 1, wherein the start-up device and the overpressure pilot device are parts of a common physical construct.
11. A fluid control system for providing start-up and overpressure relief functions to a primary fluid carrier, the system comprising:
- a main valve having an inlet, an outlet, a gallery disposed between the inlet and the outlet, a valve seat fixedly disposed in the gallery, and a valve plug slidably disposed in the gallery between a closed position engaging the valve seat and an open position spaced away from the valve seat, the valve plug being biased toward the closed position via a control spring;
- a start-up pilot device and an overpressure pilot device, each of the start-up and overpressure pilot devices including a valve body and a control assembly including a diaphragm having opposite first and second surfaces and operably coupled to a valve plug, the valve body including an inlet port, an outlet port, and a valve port disposed between the inlet port and the outlet port, the valve plug movable between a closed position engaging the valve port and an open position spaced away from the valve port,
- wherein the valve plug of the start-up pilot device is biased toward the open position by a start-up control force applied to the first surface of the diaphragm of the start-up pilot device, and the valve plug of the overpressure pilot device is biased toward the closed position by an overpressure control force applied to the first surface of the diaphragm of the overpressure pilot device;
- a first supply line providing fluid communication between the inlet of the main valve, the inlet port of the start-up pilot device, and the gallery of the main valve;
- a first exhaust line providing fluid communication away from the outlet port of the start-up pilot device to a first target destination;
- a first sensing line providing fluid communication between the second surface of the diaphragm of the start-up pilot device and a first registration source;
- a second sensing line providing fluid communication between the second surface of the diaphragm of the overpressure pilot device and a second registration source,
- wherein at least one of the first and second registration sources includes the inlet of the main valve;
- a second exhaust line providing fluid communication between the outlet port of the overpressure pilot device and a second target destination; and
- a second supply line providing fluid communication between the inlet port of the overpressure pilot device and the gallery of the main valve.
12. The system of claim 11, wherein each of the first and second registration sources comprises the inlet of the main valve.
13. The system of claim 11, wherein at least one of the first and second target destinations is the outlet of the main valve.
14. The system of claim 11, wherein at least one of the first and second target destinations is atmosphere.
15. The system of claim 11, wherein the first sensing line includes a pitot tube providing fluid communication between the inlet port of the start-up pilot device and the second surface of the diaphragm of the start-up pilot device.
16. The system of claim 11, wherein the control spring of the main valve directly engages the valve plug of the main valve to bias the valve plug toward the closed position.
17. The system of claim 11, wherein the start-up pilot device includes a start-up control spring providing the start-up control force, and the overpressure pilot device includes an overpressure control spring providing the overpressure control force.
18. The system of claim 11, further comprising a restrictor coupled into the first supply line between the inlet of the main valve and the inlet port of the start-up pilot device.
19. The system of claim 18, wherein the restrictor includes one of an adjustable restrictor or an orifice plate.
20. The system of claim 11, wherein the start-up pilot device and the overpressure pilot device are separate physical structures.
21. The system of claim 11, wherein the start-up device and the overpressure pilot device are parts of a common physical construct.
22. A method of providing start-up and overpressure relief functions to a primary fluid carrier using a fluid flow control system that includes a main valve, a start-up pilot device fluidly connected to the main valve, and an overpressure pilot device fluidly connected to the main valve, the method comprising:
- exhausting fluid from an inlet of the main valve to the outlet of the main valve through the start-up pilot device via a first supply line extending from the inlet of the main valve to an inlet port of the start-up pilot device and a first exhaust line extending from an outlet port of the start-up pilot device to an outlet of the main valve;
- automatically closing the start-up pilot device when a start-up closing pressure sensed by a diaphragm of the start-up pilot device is greater than or equal to a control pressure of the start-up pilot device;
- automatically opening the overpressure pilot device when a relief opening pressure sensed by a diaphragm of the overpressure pilot device is greater than or equal to a control pressure of the overpressure pilot device; and
- exhausting fluid from a gallery of the main valve to the outlet of the main valve while the overpressure pilot device is open via a second supply line extending from the gallery of the main valve to an inlet port of the overpressure pilot device and a second exhaust line extending from an outlet port of the overpressure pilot device to the outlet of the main valve.
23. The method of claim 22, wherein the start-up closing pressure is based on a pressure sensed at the inlet port of the start-up pilot device.
24. The method of claim 22, wherein the relief opening pressure is based on a pressure sensed at the inlet of the main valve.
25. The method of claim 22, wherein at least one of the start-up closing pressure and the relief opening pressure is based on a pressure sensed from a pressure source that is external to the main valve.
26. A method of providing start-up and overpressure relief functions to a primary fluid carrier using a fluid flow control system that includes a main valve, a start-up pilot device fluidly connected to the main valve, and an overpressure pilot device fluidly connected to the main valve, the method comprising:
- exhausting fluid from an inlet of the main valve to a first target destination through the start-up pilot device via a first supply line extending from the inlet of the main valve to an inlet port of the start-up pilot device and a first exhaust line extending from an outlet port of the start-up pilot device to the first target destination;
- automatically closing the start-up pilot device when a pressure at the inlet port of the start-up pilot device is greater than or equal to a control pressure of the start-up pilot device;
- automatically opening the overpressure pilot device when a pressure at the inlet of the main valve is greater than or equal to a control pressure of the overpressure pilot device; and
- exhausting fluid from a gallery of the main valve to a second target destination through the opened overpressure pilot device via a second supply line extending from the gallery of the main valve to an inlet port of the overpressure pilot device and a second exhaust line extending from an outlet port of the overpressure pilot device to the second target destination.
27. The method of claim 26, further comprising sensing the pressure at the inlet port of the start-up pilot device with a diaphragm of the start-up pilot device.
28. The method of claim 26, further comprising sensing the pressure at the inlet of the main valve with a diaphragm of the overpressure pilot device.
29. The method of claim 26, wherein exhausting fluid to the first target destination comprises exhausting fluid to the outlet of the main valve.
30. The method of claim 26, wherein exhausting fluid to the second target destination comprises exhausting fluid to the outlet of the main valve.
31. The method of claim 26, wherein exhausting fluid to the first target destination comprises exhausting fluid to one of atmosphere, a holding tank, or another fluid recovery system.
32. The method of claim 26, wherein exhausting fluid to the second target destination comprises exhausting fluid to one of atmosphere, a holding tank, or another fluid recovery system.
33. A fluid handling and delivery system including a pipeline or a tank connected to a fluid flow control system according to claim 1.
Type: Application
Filed: Oct 30, 2013
Publication Date: Jul 3, 2014
Patent Grant number: 9176505
Applicant: EMERSON PROCESS MANAGEMENT REGULATOR TECHNOLOGIES, INC. (McKinney, TX)
Inventors: Bruno Jean Michel Cheron (McKinney, TX), Garrett Winston (Addison, TX), Douglas J. Scheffler (McKinney, TX)
Application Number: 14/067,417
International Classification: G05D 16/06 (20060101);